Forward error correction apparatus and methods

ABSTRACT

Forward error correction apparatus and methods are described. A forward errro correction method includes: (a) computing syndromes values; (b) computing an erasure location polynomial based upon one or more erasure locations; (c) computing modified syndromes based upon the computed erasure location polynomial and the computed syndrome values; (d) computing coefficients of an error location polynomial based upon the computed modified syndromes; (e) computing a composite error location polynomial based upon the computed coefficients of the error location polynomial; (f) computing a Chien polynomial based upon the computed composite error location polynomial; (g) performing a redundant Chien search on the computed composite error location polynomial to obtain error location values; and (h) evaluating the computed Chien polynomial based upon the error location values to obtain error and erasure values. A forward erro correction system includes: first and second simultaneously accessible memory locations; first, second and third register banks; and a micro-sequencer configured to choreograph a method of correcting errors and erasures by coordinating the flow of data into the first and second memory locations and the first, second and third register banks.

This is a divisional of U.S. Ser. No. 09/393,388, filed Sep. 10, 1999, now U.S. Pat. No. 6,543,026, issued Apr. 1, 2003.

BACKGROUND OF THE INVENTION

This invention relates to apparatus and methods of forward error correction.

Forward error correction techniques typically are used in digital communication systems (e.g., a system for reading information from a storage medium, such as an optical disk) to increase the rate at which reliable information may be transferred and to reduce the rate at which errors occur. Various errors may occur as data is being read from a storage medium, including data errors and erasures. Many forward error correction techniques use an error correction code to encode the information and to pad the information with redundancy (or check) symbols. Encoded information read from a storage medium may be processed to correct errors and erasures.

Reed-Solomon (RS) encoding is a common error correction coding technique used to encode digital information which is stored on storage media A RS (n, k) code is a cyclic symbol error correcting code with k symbols of original data that have been encoded. An (n-k)-symbol redundancy block is appended to the data. The RS code represents a block sequence of a Galois field GF(2^(m)) of 2^(m) binary symbols, where m is the number of bits in each symbol. Constructing the Galois field GF(2^(m)) requires a primitive polynomial p(x) of degree m and a primitive element β, which is a root of p(x). The powers of β generate all non-zero elements of GF(2^(m)). There also is a generator polynomial g(x) which defines the particular method of encoding. A RS decoder performs Galois arithmetic to decode the encoded data. In general, RS decoding involves generating syndrome symbols, computing (e.g., using a Berlakamp computation process) the coefficients σ_(i) of an error location polynomial σ(x), using a Chien search process to determine the error locations based upon the roots of σ(x), and determining the value of the errors and erasures. After the error locations have been identified and the values of the errors and erasures have been determined, the original data that was read from the storage medium may be corrected, and the corrected information may be transmitted for use by an application (e.g., a video display or an audio transducer).

SUMMARY OF THE INVENTION

In one aspect, the invention features a method of correcting errors and erasures, comprising: (a) computing syndromes values; (b) computing an erasure location polynomial based upon one or more erasure locations; (c) computing modified syndromes based upon the computed erasure location polynomial and the computed syndrome values; (d) computing coefficients of an error location polynomial based upon the computed modified syndromes; (e) computing a composite error location polynomial based upon the computed coefficients of the error location polynomial; (f) computing a Chien polynomial based upon the computed composite error location polynomial; (g) performing a redundant Chien search on the computed composite error location polynomial to obtain error location values; and (h) evaluating the computed Chien polynomial based upon the error location values to obtain error and erasure values.

In another aspect, the invention features a system of correcting errors and erasures, comprising: first and second simultaneously accessible memory locations; first, second and third register banks; and a micro-sequencer configured to choreograph a method of correcting errors and erasures by coordinating the flow of data into the first and second memory locations and the first, second and third register banks.

Embodiments may include one or more of the following features.

The coefficients of the error location polynomial preferably are computed based upon a Berlakamp error correction algorithm.

In one embodiment, the computed syndrome values are stored in RAM memory. The computed erasure location polynomial is stored in a first register bank. The modified syndromes are stored in RAM memory. The computed coefficients of the error location polynomial are stored in a second register bank. The computed composite error location polynomial is stored in the first register bank. The computed Chien polynomial is stored in a third register bank. The computed error location values are stored in RAM memory.

Among the advantages of the invention are the following.

The invention provides a scheme in which rate at which signals are decoded may be increased by storing the results of the above-described algorithms in registers rather than in memory. In one implementation, only sixteen registers are needed for performing the Chien search, and only eighteen registers are needed to implement Berlakamp's error correction algorithm. The invention provides hardware support that significantly increases the rate at which error and erasure polynomials may be computed using a relatively small number of hardware components. The invention therefore enables forward error correction techniques to be implemented in a high speed digital signal processing chip. The invention provides a relatively simple micro-sequencer-based forward error corrector design that may be implemented with a relatively small number of circuit components, and provides improved programming functionality.

Other features and advantages will become apparent from the following description, including the drawings and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a system for reading encoded information from a storage disk.

FIG. 2A is a block diagram of an error correction digital signal processor (DSP).

FIG. 2B is a flow diagram of a cyclic three-buffer process for managing memory space in a method of correcting errors and erasures in an encoded block of data.

FIG. 3 is a diagrammatic view of an error correction code (ECC) block.

FIG. 4 is a flow diagram of a method of identifying error locations and determining error and erasure values.

FIG. 5 is a block diagram of a three-buffer method of computing an error location polynomial using the Berlakamp error correction algorithm.

FIGS. 6A-6C are block diagrams of a two-buffer method of computing an error location polynomial using the Berlakamp error correction algorithm.

FIG. 7 is a flow diagram of a method of updating intermediate values required to implement the Berlakamp error correction algorithm.

FIG. 8A is a block diagram of a multiplier for computing an erasure location polynomial.

FIG. 8B is a block diagram of another multiplier for computing an erasure location polynomial.

FIG. 9 is an apparatus for searching for the roots of a composite error location polynomial.

FIGS. 10A-10D are block diagrams of a method of computing errors and erasures.

DETAILED DESCRIPTION

Referring to FIG. 1, a system 10 for reading encoded information from a storage disk 12 (e.g., a magnetic memory disk, a compact disk (CD), or a digital video disk (DVD)) includes a raad head 14, a demodulator 16, an error correction digital signal processor (EC DSP) 18, and an audio-video (AV) decoder 20. In operation, read head 14 scans the surface of storage disk 12 and reads data stored on storage disk 12 with a magnetic transducer or an optical transducer. The data preferably is encoded with a RS cyclic redundancy code. Demodulator 16 extracts digital information from the signal produced by read head 14. EC DSP 18 synchronizes to the extracted digital information, performs a 16-bit to 8-bit conversion and, as explained in detail below, corrects the extracted information based upon the redundant information encoded into the information stored on storage disk 12. In particular, EC DSP 18 identifies error locations and determines the values of errors and erasures to correct the information read from storage disk 12. AV decoder 20 generates audio and video data signals from the corrected data signal received from EC DSP 18. The audio and video data signals may be transmitted to an application unit (e.g., a television or a computer) to present the audio and video signals to a user.

As shown in FIG. 2A, data that is read from storage disk 12 enters EC DSP 18 as a RZ signal with sample clock or as an NRZ signal without a sample clock. The NRZ signal passes through a bit clock regenerator 22 which performs a clock recovery operation on the signal. EC DSP includes a multiplexor 24, a first stage processor 26, a subcode/ID processor 28, a memory interface 30, and an error corrector 32. Multiplexor 24 transmits the data signal to first stage processor 26 that performs the processes of synchronization, demodulation, and deinterleaving. After these processes have been performed, first stage processor 26 loads one error correction code (ECC) block into memory (see FIG. 3). Memory interface 30 reads the ECC block from memory and calculates syndromes, which are passed to error corrector 32. Error corrector 32 computes error locations and values and passes this information to memory interface 30, which writes this information back into the memory locations from which memory interface 30 originally retrieved the erroneous data. Memory interface 30 descrambles the corrected data, checks the data for errors, and places the corrected data into a track buffer from which AV decoder 20 will receive the corrected data.

Referring to FIG. 2B, memory interface 30 facilitates decoding in real time by cycling through three separate buffer locations as follows. At time T₀, first stage processor 26 that performs the processes of synchronization, demodulation, and deinterleaving, and a first ECC block is stored in buffer 1 (step 40). At time T₁:

memory interface 30 reads the ECC block from buffer 1, calculates syndromes and passes the syndromes to error corrector 32 (step 42);

memory interface 30 writes the corrected error information to the corresponding memory locations in buffer 1 (step 44); and

a second ECC block is stored in buffer 2 (step 45).

At time T₂

memory interface 30 reads the ECC block from buffer 2, calculates syndromes and passes the syndromes to error corrector 32 (step 46);

memory interface 30 writes the corrected error information to the corresponding memory locations in buffer 2 (step 48);

memory interface 30 descrambles the corrected data in buffer 1, checks the data for errors, and places the corrected data into a track buffer from which AV decoder 20 will receive the corrected data (step 50); and

a third ECC block is stored in buffer 3 (step 51).

At time T₃

memory interface 30 reads the ECC block from buffer 3, calculates syndromes and passes the syndromes to error corrector 32 (step 52);

memory interface 30 writes the corrected error information to the corresponding memory locations in buffer 3 (step 54);

memory interface 30 descrambles the corrected data in buffer 2, checks the data for errors, and places the corrected data into a track buffer from which AV decoder 20 will receive the corrected data (step 56); and

a third ECC block is stored in buffer 1 (step 57).

At time T₄

memory interface 30 reads the ECC block from buffer 1, calculates syndromes and passes the syndromes to error corrector 32 (step 58);

memory interface 30 writes the corrected error information to the corresponding memory locations in buffer 1 (step 60);

memory interface 30 descrambles the corrected data in buffer 3, checks the data for errors, and places the corrected data into a track buffer from which AV decoder 20 will receive the corrected data (step 62); and

a third ECC block is stored in buffer 2 (step 63).

The decoding of subsequent ECC blocks continues by cycling through the process steps of times T₂, T₃ and T₄ (step 64).

Referring to FIG. 3, the ECC block loaded into memory by first stage processor 26 includes a data block 70, an RS PO block 72, and an RS PI block 74. Data block 70 consists of 192 rows of data, each containing 172 bytes (B_(ij)). RS PO block 72 consists of 16 bytes of parity added to each of the 172 columns of data block 70. The parity was generated using a (208, 192) RS code and a generator polynomial given by ${G_{PO}\quad (x)} = {\prod\limits_{i = 0}^{15}\quad \left( {x + \alpha^{i}} \right)}$

RS PI block 74 consists of 10 bytes of parity added to each of the 208 rows forming data block 70 and RS PO block 72. The parity was generated using a (182, 172) RS code and a generator polynomial given by ${G_{PI}\quad (x)} = {\prod\limits_{i = 0}^{9}\quad \left( {x + \alpha^{i}} \right)}$

For both the (208, 192) and (182, 172) RS codes, the primitive polynomial is given by P(x)=x⁸+x⁴+x³+x²+1. The resultant ECC block contains 37,856 bytes.

Referring to FIG. 4, in one embodiment, error corrector 32 identifies error locations and determines values for errors and erasures as follows. Syndromes S_(i) are generated by memory interface 30 by evaluating the received data at α^(i) (step 80). If there are erasures present (step 82), an erasure location polynomial σ′(x) is computed, and a set of modified syndromes T_(i) is computed (step 84). Error location polynomial σ(x) is computed using Berlakamp's method (step 86). Error locations X_(L) are identified using a Chien search (step 88). Finally, Forney's method is used to identify error and erasure values Y_(L) (step 90).

Each of the steps 80-90 is described in detail below.

Generating Syndromes (Step 80)

Assuming that the transmitted code vector is v(x)=Σv_(j)x^(j) (where j=0 to n−1) and that the read channel introduces the error vector e(x)=Σe_(j)x^(j) (where j=0 to n−1), the vector received by error corrector 32 is given by r(x)=v(x)+e(x). The i^(th) syndrome is defined as S_(i)=r(α^(i)). Accordingly, by evaluating the received signal r(x) at α^(i), each of the syodromes S_(i) may be generated

No Erasures Are Present (Step 82)

If no erasures are present (step 82; FIG. 4), error locations and error values may be determined as follows.

Computing Error Location Polynomial (Berlakamp's Method) (Step 86)

The error location polynomial is given by σ(x)=Π(1+xX_(j))=Σσ_(j)x^(j)+1, where j=1 to t and X_(j) correspond to the error locations. Thus, the error locations X_(L) may be determined by identifying the roots of σ(x).

Berlakamp's method is used to compute the coefficients σ_(i) of σ(x) based upon the generated syndrome values S_(i). In accordance with this approach, the following table is created with the values for the first rows entered as shown:

TABLE 1 Berlakamp's Method μ σ^(μ)(x) d_(μ) 1_(μ) μ − 1_(μ) −1 1 1  0 −1 0 1 S₀ 0 0 1 2 . . . 2t

The remaining entries are computed iteratively one row at a time. The (u+1)^(th) is computed from the prior completed rows as follows:

if d_(μ)=0, then σ^(μ+1)(x)=σ^(μ)(x) and 1_(μ+1)=1_(μ);

if d_(μ)≠0, identify another row p which is prior to the μ^(th) row such that d_(p)≠0 and the number p−1_(p) (last column of Table 1) has the largest value, and compute the following:

σ^(μ+1)(x)=σ^(μ)(x)+d_(μ)d_(p) ⁻¹x^(μ−p)σ^(p)(x);

1_(μ+1)=max(1_(μ), 1_(p)+μ−p);

d_(μ+1)=S_(μ+1)+σ₁ ^(μ+1)(x)S_(μ)+σ₂ ^(μ+1)(x)S_(μ−1)+ . . . +σ_(1μ+1) ^(μ+1)(x)S_(μ−1−1μ+1)

The method is initialized with μ=0 and p=−1. The coefficients σ_(i) of σ(x) are computed by the time the bottom row of Table 1 has been completed because σ(x)=σ^(2t)(x).

The above method may be implemented by maintaining σ^(μ+1)(x), σ^(μ)(x), and σ^(p)(x) in three registers, computing σ^(μ+1)(x) with one cycle updates, and computing d_(μ+1) with one hardware instruction.

Referring to FIG. 5, in one embodiment, σ^(μ+1)(x), σ^(μ)(x), and σ^(p)(x) are maintained in three polynomial buffers 100, 102, 104 (8-bit wide registers). At time k, σ^(μ+1)(x) is stored in buffer 1, σ^(μ)(x) is stored in buffer 2, and σ^(p)(x) is stored in buffer 3. At time k+1, σ^(μ+1)(x) is stored in buffer 2, σ^(μ)(x) is stored in buffer 1, and σ^(p)(x) is stored in buffer 3. At the end of each iteration, the pointers for σ^(μ+1)(x), σ^(μ)(x), and σ^(p)(x) are updated to reflect the buffers in which the respective polynomials are stored. In this embodiment, the column values for d_(μ), 1_(μ), and μ−1_(μ) are stored in RAM.

Referring to FIGS. 6A-6C, in another embodiment, σ^(μ+1)(x), σ^(μ)(x), and σ^(p)(x) are maintained in two registers 106, 108; the column values for d_(μ), 1_(μ), and μ−1_(μ) are stored in RAM. With a software-controlled bank switch option, a customized hardware instruction may be used to update σ^(μ+1)(x) from σ^(μ)(x) using registers 106, 108 as follows:

(1) At time k, if d_(μ)=0 and p−1_(p)≧μ−1_(μ), then σ^(μ+1)(x)=σ^(μ)(x) and σ^(p)(x) does not change. At time k+1, σ^(μ+1)(x) and σ^(μ)(x) remain in their current buffers and d_(μ+1) is recomputed and saved to memory along with the value of (μ+1−1_(μ+1)).

(2) At time k, if d_(μ)=0 and p−1_(p)<μ−1_(μ), then σ^(μ+1)(x)=σ^(μ)(x) and σ^(p)(x)=σ^(μ)(x). At time k+1, the buffer containing σ^(p)(x) at time k is updated with σ^(μ)(x), d_(μ+1) is recomputed and saved to memory along with the value of (μ+1−1_(μ+1)), and d_(p), 1_(p), and p−1_(p) are updated in RAM (FIG. 6A)

(3) At time k, if d_(μ)≠0 and p−1_(p)≧μ−1_(μ), then σ^(μ+1)(x)=σ^(μ)(x)+d_(μ)d_(p) ⁻¹x^(μ−p)σ^(p)(x) and σ^(p)(x)=σ^(p)(x). At time k+1, the buffer containing σ^(μ)(x) at time k is updated with σ^(μ)(x)+d_(μ)d_(p) ⁻¹x^(μ−p)σ^(p)(x) by updating the x⁸ term in σ^(p)(x) and progressing to x⁰ (FIG. 6B). If the degree of x^(σ−p)σ^(p)(x)>8, then an uncorrectable bit is set in a register.

(4) At time k, if d_(μ)≠0 and p−1_(p)<μ−1_(μ), then σ^(μ+1)(x)=σ^(μ)(x)+d_(μ)d_(p) ⁻¹x^(μ−p)σ^(p)(x) and σ^(p)(x)=σ^(μ)(x). At time k+1, the buffer containing σ^(p)(x) at time k is updated with σ^(μ)(x)+d_(μ)d_(p) ⁻¹x^(μ−p)σ^(p)(x). Software triggers a bank swap 109 between the two buffers, whereby the physical meaning of the two buffers is swapped. This allows the buffers to be updated simultaneously without any intermediary storage space. The updating begins with the x⁸ term in σ^(p)(x) and progressing to x⁰. If the degree of x^(μ−p)σ^(p)(x)>8, then an uncorrectable bit is set in a register (FIG. 6C).

Referring to FIG. 7, d_(μ+1) is computed with a customized hardware instruction as follows. A register R1 is initialized to 1_(μ+1)(step 110). A register dmu_p1 is initialized to S_(μ+1) (step 112). A pointer tmp_synd_addrs is initialized to point to the address of S_(μ) (step 114). The value at the memory address identified in register tmp_synd_addrs is multiplied by the contents of X^(i) stored in the buffer which contains σ_(μ) (step 116). The contents of register dmu_p1 are added to the product of the result obtained in step 116 (step 118). The content of the register identified by the pointer tmp_synd_addrs is decremented (step 120). The value of I is incremented by 1 (step 122). The 1_(μ+1) register is decremented by 1 (step 124). If the value contained in the 1_(μ+1) register is zero (step 126), the process is terminated (step 128); otherwise, the value stored in register tmp_synd_addrs is multiplied by the contents of X^(i) stored in the buffer which contains σ_(μ) (step 116) and the process steps 118-126 are repeated.

At the end of the above-described process (step 86), row 2t of Table 1 contains the coefficients σ_(i) of the error location polynomial σ(x) (i.e., σ(x)=σ^(2t)(x)).

Identifying Error Locations (Chien Search) (Step 88)

Once the coefficients σ_(i) of the error location polynomial σ(x) have been computed, the error locations X_(L) are determined by searching for the roots of σ(x) using conventional Chien searching techniques.

Determining Error Values (Forney's Method) (Step 90)

Error values Y_(L) are computed from the error locations X_(L) and the syndromes S_(i) as follows: ${Y_{i} = \frac{\Omega \quad \left( X_{i}^{- 1} \right)}{\prod\limits_{j \neq i}^{\quad}\quad \left( {1 + \frac{X_{j}}{X_{i}}} \right)}},$

where Ω(x)=S(x)σ(x) (mod x^(2t)) and ${S\quad (x)} = {\sum\limits_{k = 1}^{2t}\quad {S_{k - 1}\quad {x^{k - 1}.}}}$

Erasures Are Present (Step 824)

If erasures are present (step 82; FIG. 4), error locations and error and erasure values may be determined as follows.

Computing Erasure Location Polynomial (Step 83)

An erasure location polynomial is defined as follows:

σ′(z)=Π(z+Z _(j))=Πσ′_(s−j) z ^(j)+σ′_(s)(j=1 to s),

where s is the number of erasures present and Z_(i) are the known locations of the erasures. This expression may be rewritten as follows: $\begin{matrix} {{\sigma^{\prime}\quad (z)} = \quad {\left( {z^{s - 1} + {Q_{s - 2}\quad z^{s - 2}} + {\ldots \quad Q_{1}\quad z} + Q_{0}} \right) \times \left( {z + Z_{s}} \right)}} \\ {= \quad {z^{s} + {\left( {Z_{s} + Q_{s - 2}} \right)\quad z^{s - 1}} + {\left( {{Q_{s - 2}\quad Z_{s}} + Q_{s - 3}} \right)\quad z^{s - 2}} + {\ldots \quad \left( {{Q_{1}\quad Z_{s}} +} \right.}}} \\ {{\left. \quad Q_{0} \right)\quad z} + {Q_{0}\quad Z_{s}}} \end{matrix}$

Referring to FIG. 8A, in one embodiment, this expression for the erasure location polynomial σ′(x) is computed recursively with s 8-bit wide registers 130. In operation, the following steps are performed: (a) an erasure location and the output of a given register in a series of k registers are multiplied to produce a product; (b) if there is a register immediately preceding the given register in the series of registers, the product is added to the output of the preceding register to produce a sum; (c) the sum (or the product, if a sum was not produced) is applied to the input of the given register, (d) steps (a)-(c) are repeated for each of the registers in the series; (e) each of the registers in the series is clocked to transmit register input values to register outputs; and (f) steps (a)-(e) are repeated for each of the erasure locations. The output of a first register is initialized to 1, and the outputs of the remaining registers is initialized to 0.

Referring to FIG. 8B, in another multiplier embodiment, a customized hardware instruction may be used to compute σ′(x) using one multiplier 132 and one adder 134. In operation, the following steps are performed: (a) an erasure location is applied to an input of a input register; (b) an output of a given register in a series of registers and an output of the input register are multiplied to produce a product; (c) the product and an output of the dummy register are added to produce a sum; (d) the sum is applied to an input of a subsequent register immediately following the given register; (e) the subsequent register is treated as the given register and steps (a)-(d) are repeated for each of the erasure locations. For example, the multiplier may be cycled as follows:

cycle 1: initialize all registers to 1 and dummy register 136 to 0; set D₀=Z₁ and sel=0;

cycle 2: set Q₀=Z₁; set D=Z₂;

cycle 3: set Z_(s)=Z₂ and D=Z₃;

cycle 4: set Q_(i−1)=Q₀, Q₀=D₀, and sel=1;

cycle 5: set Q₁=D₁, sel=0, Z_(s)=Z₃, and D=Z₄.

The performance of cycles 1-5 results in the computation of two erasure multiplications. Q₂, Q₁ and Q₀ now hold the second degree erasure polynomial whose roots are Z₁ and Z₂. Additional multiplications may be computed by continuing the sequence of cycles.

The erasure location polynomial σ′(x) is used to compute modified syndrome values T_(i) as follows.

Computing Modified Syndromes (step 84)

The modified syndromes T_(i) are defined as follows: $T_{i} = {{\sum\limits_{j = 0}^{s}\quad {\sigma_{j}^{l}\quad S_{i + s - j}\quad {for}\quad 0}} \leq i \leq {{2t} - s - 1}}$

Software running on the micro-sequencer may load σ_(j)′, S_(i+s−j) from memory and perform the multiplication and accumulation. Th expression for T_(i) may be rewritten as: ${T_{i} = {\sum\limits_{m = 1}^{a}\quad {E_{m}\quad X_{m}^{i}}}},{{{for}\quad 0} \leq i \leq {{2t} - s - 1}}$

where E_(m)=Y_(m)σ′(X_(m)), α corresponds to the number of errors, the values X_(m) correspond to the unknown error locations, and the values Y_(m) corresponds to the unknown error and erasure values.

The modified syndrome values T_(i) may be used to compute the coefficients σ_(i) of the error location polynomial σ(x).

Computing Error Location Polynomial (Berlakamp's Method) (Step 86)

Because the modified syndromes represent a system of equations that are linear in E_(i) and nonlinear in X_(i), Berlakamp's method (described above; step 86) may be used to compute the coefficients σ_(i) of the error location polynomial σ(x) from the modified syndromes T_(i) based upon the substitution of the modified syndrome values T_(i) for the syndrome values S_(i).

At the end of the process (step 86), Table 1 contains the coefficients σ_(i) of the error location polynomial σ(x).

Identifying Error Locations (Chien Search) (Step 88)

Once the coefficients σ_(i) of the error location polynomial σ(x) have been computed, the error locations X_(L) may be determined by searching for the roots of σ(x) using conventional Chien searching techniques.

In an alternative embodiment, the error locations X_(L) are determined by searching for the roots of a composite error location polynomial σ″(x)=x^(s)σ′(x⁻¹)σ(x) using conventional Chien searching methods. This approach simplifies the hardware implementation needed to compute the error and erasure values.

During the Chien search, the following expressions are evaluated and tested for zero:

σ″(α⁻⁰)=σ″(1)=σ″₁₆+σ″₁₅+ . . . +σ″₁σ″₀

σ″(α⁻¹)=σ″(α²⁵⁴)=σ″₁₆α^(254x16)+σ″₁₅α^(254x15)+ . . . +σ″₁α^(254x1)+σ″₀

σ″(α⁻²)=σ″(α²⁵³)=σ″₁₆α^(253x16)+σ″₁₅α^(253x15)+ . . . +σ″₁α^(253x1)+σ″₀

. . .

σ″(α⁻²⁰⁷)=σ″(α⁴⁸)=σ″₁₆α^(48x16)+σ″₁₅α^(48x15)+ . . . +σ″₁α^(48x1)+σ″₀

Referring to FIG. 9, a circuit 140 may be used to evaluate the above expression. Circuit 140 is initialized to σ″₁₆, σ″₁₅, . . . , σ″₀. In one operation, σ″(1) is obtained. During the first 47 clocking cycles a root counter 144 is monitored for new roots and, when a new root is detected, a bit flag is set to high, indicating that an uncorrectable error has occurred. Each clock cycle from clock number 48 through clock number 254 generates σ″(48) through σ″(254). After the 254^(th) cycle, firmware identified a data block as uncorrectable if: (1) the bit flag is set to high; or (2) value of root counter 144 does not equal v+s, where v is the power of σ″(x) and s is the number of erasures.

In an alternative embodiment, the σ″₀ register is not included and, instead of testing against zero, the sum of the remaining registers is tested against 1.

At the end of the above-described process (step 88), the error locations X_(L) have been identified. By performing a redundant Chien search on the composite error location polynomial σ″(x), computation time and implementation complexity may be reduced relative to an approach that performs a Chien search on the error location polynomial σ(x) because this redundant Chien search provides (through the “to Forney” signal) the value of the denominator σ″₀(X_(L) ⁻¹) for the error and erasure values Y_(L), as described in the following section.

Determining Error and Erasure Values (Forney's Method) (Step 90)

The error and erasure values Y_(L) are computed from the error locations X_(L), the syndromes S_(i) and a composite error location polynomial σ″(x) as follows: ${Y_{l} = \frac{\Omega \left( X_{i}^{- 1} \right)}{\prod\limits_{j \neq i}\quad \left( {1 + \frac{X_{j}}{X_{i}}} \right)}},$

where Ω(x)=S(x)σ″(x) (mod x^(2t)), S(x)=ΣS_(k−1)x^(k−1), and σ″(x)=x^(s)σ′(x⁻¹)σ(x). This expression may be rewritten as follows. Assuming τ=v+s, σ″(x) may be rewritten as: ${\sigma^{''}(x)} = {{{\sigma_{\tau}x^{\tau}} + {\sigma_{\tau - 1}x^{\tau - 1}} + \ldots + {\sigma_{1}x^{1}} + \sigma_{0}} = {\prod\limits_{j = 1}^{\tau}\quad \left( {1 + {X_{f}x}} \right)}}$

Based upon this result, the erasure value polynomial evaluated at σ″(x) and σ″(X_(L) ⁻¹) (i.e., D_(x)(σ″(x)) and D_(x)(σ″(X_(L) ⁻¹))) may be given by: ${D_{x}\left( {\sigma^{''}(x)} \right)} = {{\sum\limits_{L = 1}^{\tau}\quad {\prod\limits_{j \neq L}\quad {{X_{L}\left( {1 + {X_{f}x}} \right)}\quad {and}\quad {D_{x}\left( {\sigma^{''}\left( X_{L}^{- 1} \right)} \right)}}}} = {X_{L}{\prod\limits_{j \neq L}\quad \left( {1 + \frac{X_{j}}{X_{L}}} \right)}}}$

The erasure location polynomial σ″(x) may be rewritten in terms of its odd σ_(o)″ and even σ_(e)″ components: σ″(x)=σ_(o)″(x)+σ_(e)″(x), where σ_(o)″(x)=σ₁″x+σ₃″x³+ . . . and σ_(o)(x)=σ₀″+σ₂″x²+ . . . Now, since the erasure value polynomial evaluated at σ″(x) may be rewritten as: D_(x)(σ″(x))=σ″₁+σ″₃x²+σ″₅x⁴+ . . . , the following expression is true:

X _(L) ⁻¹ D _(x)(σ″(X _(L) ⁻¹))=σ₁ ″X _(L) ⁻¹+σ₃ ″X _(L) ⁻³+σ₅ ″X _(L) ⁻⁵+ . . . =σ_(o)″(X _(L) ⁻¹)

Accordingly, ${\sigma_{0}^{''}\left( X_{L}^{- 1} \right)} = {\prod\limits_{j \neq L}\quad {\left( {1 + \frac{X_{j}}{X_{L}}} \right).}}$

Thus, the error and erasure values Y_(L) may be given by: $Y_{L} = \frac{\Omega \left( X_{L}^{- 1} \right)}{\sigma_{0}^{''}\left( X_{L}^{- 1} \right)}$

The denominator of the above expression is obtained from the “to Forney” signal of FIG. 9. The numerator may be computed by initializing the flip flops 142 in FIG. 9 with the values of Ω_(i) rather than the values of σ_(i); the values of Ω_(i) may be computed by software running on the micro-sequencer.

Memory Management

The rate at which signals are decoded may be increased by storing the results of the above-described algorithms in registers rather than in memory. In the following implementation, only sixteen registers are needed for performing the Chien search, and only eighteen registers are needed to implement Berlakamp's method (described above) for computing the coefficients σ_(i) of the error location polynomial σ(x) from the modified syndromes T_(i). In this implementation, a micro-sequencer 190 issues instructions 192 that execute the decoding process and coordinate the flow of data into the registers and memory locations.

Referring to FIGS. 10A-10D, in one embodiment, errors and erasures may be computed by error corrector 32 implementing one or more of the above-described methods as follows. The following description assumes that errors and erasures are present in the received EC data block. In accordance with this method, error corrector 32 performs the following tasks serially: (1) compute the erasure location polynomial σ′(x) for erasures; (2) compute the modified syndromes T_(i); (3) perform Berlakamp's method to obtain the coefficients σ_(i) of the error location polynomial σ(x); (4) compute the composite error location polynomial σ″(x); (5) compute the Chien polynomial Ω(x); (6) perform a redundant Chien search on σ″(x) to obtain the error locations X_(L); and (7) evaluate Ω(X_(L) ⁻¹) to obtain the error and erasure values Y_(L).

As shown in FIG. 10A, based upon the predetermined erasure locations, which are stored in RAM memory 200, the coefficients 201 of the erasure location polynomial σ′(x) are computed and stored in register bank 202 (step 204). The modified syndromes T_(i) are computed based upon the coefficients of σ′(x) and the syndrome values 205 (S_(i)) which are stored in RAM memory 206 (step 208); the modified syndromes T_(i) are stored in RAM memory 210. The modified syndromes T_(i) are used to compute the coefficients 211 of error location polynomial σ(x) (step 212); these coefficients are stored in register bank 214 and in RAM memory 216.

Referring to FIG. 10B, composite error location polynomial σ″(x) (=x^(s)σ′(x⁻¹)σ(x)) is computed based upon the stored coefficients 211 of the error location polynomial σ(x) and the stored coefficients 201 of the erasure location polynomial σ′(x) (step 218). The coefficients of σ″(x) are computed in software and are stored in RAM memory 216 and in register bank 202. The Chien polynomial Ω(x) (=S(x)σ″(x)) is computed based upon the stored coefficients 220 of σ″(x) and the stored syndrome values 205 (S_(i)) (step 222). The computed coefficient values 224 of Ω(x) are stored in register bank 226.

As shown in FIG. 10C, a Chien search is performed (step 228). During the Chien search, the values 232, 234 of log_(α)(X_(L) ⁻¹) (Chien locations) and σ_(o)″(X_(L) ⁻¹) are computed, respectively. The values 232 (log_(α)(X_(L) ⁻¹)) are written to RAM memory location 200. The inverses of values 234 (σ_(o)″(X_(L) ⁻¹)) are computed and stored in memory location 216 (step 236).

Referring to FIG. 10D, the coefficient values 224 of Ω(x) are written from register bank 226 to register bank 202. The values 238 (log_(α)(X_(L+1)/X_(L))) are clocked into register bank 202 (step 240). The errors and erasures values Y_(L) are computed by multiplying the inverse of the composite error location polynomial evaluated at error location X_(L) and the Chien polynomial values evaluated at X_(L) (step 242): $Y_{L} = \frac{\Omega \left( X_{L}^{- 1} \right)}{\sigma_{0}^{''}\left( X_{L}^{- 1} \right)}$

The computed error and erasure values Y_(L) are stored in RAM memory 210.

Other embodiments are within the scope of the claims. 

What is claimed is:
 1. A system for correcting errors and erasures in a data signal, comprising: first, second, third and fourth simultaneously accessible memory locations; first, second and third register banks each capable of storing a plurality of polynomial coefficients; and a micro-sequencer configured to correct the errors and erasures by (i) executing a decoding process and (ii) coordinating a flow of the polynomial coefficients among the first, second, third and fourth memory locations and the first, second and third register banks.
 2. The system of claim 1, wherein the micro-sequencer is configured to perform the following sequence of steps: (a) compute syndromes values; (b) compute an erasure location polynomial based upon one or more erasure locations; (c) compute modified syndromes based upon the computed erasure location polynomial and the computed syndrome values; (d) compute coefficients of an error location polynomial based upon the computed modified syndromes; (e) compute a composite error location polynomial based upon the computed coefficients of the error location polynomial; (f) compute a Chien polynomial based upon the computed composite error location polynomial; (g) perform a redundant Chien search on the computed composite error location polynomial to obtain error location values; and (h) evaluate the computed Chien polynomial based upon the error location values to obtain error and erasure values.
 3. The system of claim 2, wherein the coefficients of the error location polynomial are computed based upon a Berlakamp error correction algorithm.
 4. The system of claim 3, wherein: the coefficients of the error location polynomial are computed using eighteen registers.
 5. The system of claim 3, wherein: the coefficients of the error location polynomial are computed in response to one or more hardware instructions.
 6. The system of claim 2, wherein the computed syndrome values are stored in the first memory locations.
 7. The system of claim 6, wherein the computed erasure location polynomial is stored in the first register bank.
 8. The system of claim 7, wherein the modified syndromes are stored in the second memory locations.
 9. The system of claim 8, wherein the computed coefficients of the error location polynomial are stored in the second register bank.
 10. The system of claim 9, wherein the computed composite error location polynomial is stored in the first register bank.
 11. The system of claim 10, wherein the computed Chien polynomial is stored in the third register bank.
 12. The system of claim 11, wherein the computed error location values are stored in the second memory locations.
 13. The system of claim 2, wherein: the redundant Chien search is performed using sixteen registers.
 14. The system of claim 1, wherein (i) the first, second, third and fourth memory locations, (ii) the first, second and third register banks and (iii) the micro-sequencer are part of an error corrector circuit configured to generate corrected error and erasure values in response to syndromes.
 15. The system of claim 14, further comprising: a memory interface configured to (i) read one or more error correction code (ECC) blocks from a memory and (ii) generate the syndromes in response to the ECC blocks.
 16. The system of claim 15, further comprising: a processor configured to generate the ECC blocks in response to the data signal and write the ECC blocks to the memory, wherein the processor performs synchronization, demodulation and deinterleaving of the data signal.
 17. The system of claim 15, wherein: the memory interface is further configured to write the corrected error and erasure values to the memory at corresponding error and erasure locations.
 18. The system of claim 17, wherein: the memory interface is further configured to (i) descrammble data corrected in response to the corrected error and erasure values, (ii) check the corrected data for errors and (iii) store the corrected data to a track buffer.
 19. The system of claim 1, wherein: the micro-sequencer is further configured to issue instructions configured to (i) execute the decoding process and (ii) coordinate the flow of the polynomial coefficients.
 20. The system of claim 1, wherein the first, second, third and fourth simultaneously accessible memory locations comprise random access memory (RAM). 